Happy New Year #MathTwitter! Let's start 2022 w/ Part 1 of a fun series: "Groups you Never Knew Existed...and others you can't POSSIBLY live without!"

Today we'll see the "diquaternions", a term you've never heard of b/c I made it up last month. Let's dig in! 🧵👇

1/17

We'll start with the familiar quaternion group Q_8. Shown here are several Cayley diagrams, a Cayley table, cycle diagram, subgroup lattice, its partition by conjugacy classes, and an action diagram of Aut(Q_8). Each of these highlights different structural features.

2/17

Next, have you ever wondered what would happen if you replace i=e^{2\pi i/4} in Q_8 with a larger root of unity?

These are the dicyclic groups. Here is Dic_6, for n=6. Note that n=4 gives Q_8.

The last two pictures highlight the orbit structure (cyclic subgroups).

3/17

The quotient Dic_n / <-1> is always dihedral. Here are several ways to see that.

Even though these groups generalize Q_8, when n is a power of two, Dic_n is called a "Generalized Quaternion Group", because it shares properties with Q_8 that other dicyclic groups don't.

4/17

In particular, "gen. quaternion groups" never break up as a semi-direct product of any proper subgroups, because every non-trivial subgroup contains -1. So no two can intersect trivially.

Here are the subgroup lattices of Q_{32}, Q_{16}, and Q_8. Compare to Dic_6, above.

5/17

Now, let's talk 2x2 representations of these groups.

There is a canonical way (see images) to represent

D_n = <r, f> = <R_n, F>, and
Q_8 = <i, j> = <R_4, S>.

Here: R_n = "rotation", F = "flip", and S = "j".

Put these together to get

Dic_n = <r, j> = <R_n, S>!

6/17

So, dicyclic groups are what we get by replacing R_4 with R_n in Q_8.

But there's something else we can do: start with the QUATERNION group Q_8 and add the *reflection* matrix F from the DIHEDRAL group D_n!

This defines the "DIQUATERNION group", DQ_8.

7/17

You've never heard the term "diquaternion" because I coined it 2 weeks ago. It consists of the matrices

DQ_8 = { ±I, ±X, ±Y, ±Z, ±iI, ±iX, ±iY, ±iZ},

where X, Y, Z are the "Pauli matrices" from quantum physics.

This is also called the "Pauli group on 1 qubit".

8/17

Fun exercise, good for students: show that the quotient DQ_8 / <-I> is Z2^3, by making a Cayley table with the following 8 entries:

±I, ±X, ±Y, ±Z, ±iI, ±iX, ±iY, ±iZ,

like we did with Q_8 and Dic_6 in tweets 2 & 4.

Show that it has the structure of this.

9/17

Another fun exercise for your algebra students:

Label the following cycle diagram with elements from the diquaternion group DQ_8. This will help see different aspects of its structure. It has 4 max'l orbits of size-4, and 5 of size 2.

10/17

Purely visually, we can find three index-2 subgroups H of DQ_8, isomorphic to

D_4 (the outer ring)
Q_8 (yellow nodes)
C4 x C2 (nodes along the x & y axes).

Another fun exercise for your students: for which of these H does DQ_8 ≅ H ⋊ C2?

11/17

Do you see what's coming next? What if we replace "R_4" in the rep. for DQ_8 with a different rotation R_n, like we did to generalize Q_8 --> Dic_n.

For n=2^k, this defines the "Generalized Diquaternion Group". Here is DQ_{16}.

12/17

I've got lots of materials to share. I'm also finishing a ~600 page book, that I'm hoping will completely change how algebra is taught. My materials (slides, HW, videos) will always be freely available. But there's no going back!

Here's to a great 2022, Happy Near Year!

17/17

UPDATE & CORRECTION: On #10/17, I had a blank cycle diagram that was for the wrong group, V4⋊C4. It has the same # of elts of each order as DQ_8, but is not isomorphic.

I just made these diagrams. 2 different ways to label DQ_8: one w/ Pauli matrices, and the other...

18/17

...with the elements of <R,S,F>, where Q_8=<R,S> and D_n = <R_n, F>.

Here are their cycle diagrams w/ the same labelings. The yellow nodes highlight the subgroup Q_8.

I found this informative, it's something I simply had never done until just now. Hope you enjoy!

19/17